JP6267145B2 - Station side apparatus and optical transmission system - Google Patents

Description

  The present invention relates to an OLT in an optical transmission system that performs frame transfer processing between a plurality of ONUs (subscriber side devices: Optical Network Unit) connected via a PON (Passive Optical Network) and a host device. More specifically, the present invention relates to an OLT and an optical transmission system that enable efficient communication with a large number of ONUs (station side device: Optical Line Terminal) and an optical transmission system including the station side device.

  In recent years, as a PON used in an optical access system such as FTTH (Fiber To The Home), standardization of 10 G-EPON (10 Gigabit Ethernet Passive Optical Network: Ethernet is a registered trademark) in IEEE 802.3av in 2009. A feature of 10G-EPON is that 10-times high-speed transmission is possible as compared with GE-PON (Gigabit Ethernet Passive Optical Network: Non-Patent Document 1) that is already widely used. Furthermore, there is a feature that existing GE-PON and 10G-EPON can be used together.

  When using a mixture of GE-PON and 10G-EPON, in downlink signal transmission, WDM (Wavelength Division Multiplexing) technology using different wavelengths for 1G downlink signals and 10G downlink signals is used, and between 1G downlink signals and 10G A TDM (Time Division Multiplexing) technique is used for each of the downstream signals. On the other hand, in upstream signal transmission, the same wavelength is used for the 1G upstream signal and the 10G upstream signal, and the 1G upstream signal and the 10G upstream signal are combined to use a TDMA (Time Division Multiple Access) technique. That is, three different wavelengths are used for the 1G downstream signal, the 10G downstream signal, and the upstream signal.

Such an optical transmission system using GE-PON or 10G-EPON is called a GE-PON system or 10G-EPON system.
FIG. 9 is a diagram illustrating a configuration example of a conventional GE-PON system. The GE-PON system 900 shown in FIG. 1 includes an OLT (station side device) 90, an optical splitter 91, and a plurality of ONUs (subscriber side devices) 92, and is connected via the optical splitter 2. A plurality of ONUs 3 are accommodated in the OLT 90.

  As shown in FIG. 9, the GE-PON OLT 90 includes an optical transceiver 91 and a PON control circuit 92. In the OLT 90, the optical transceiver 91 converts the electrical signal related to the downstream frame to the ONU 92 connected to the optical transceiver 91 into an optical signal, and converts the optical signal related to the upstream frame from the ONU 92 into an electrical signal. The photoelectric conversion is performed. The PON control circuit 92 transfers an upstream frame from the ONU 3 received by the optical transceiver 91 to a higher-level device (not shown), and transfers a downstream frame received from the higher-level device to the optical transceiver 91.

  In the OLT 90, the maximum number of ONUs 92 that can be connected to one optical transceiver 91 is 32, which is defined by the IEEE standard. Therefore, when it is necessary to connect 33 or more ONUs 92 as stations that accommodate the ONUs 92, a plurality of optical splitters 91 are provided between the OLT 90 and the ONUs 92 as shown in FIG. A configuration using 91_m and a plurality of PON control circuits 92_1 to 92_m is a general configuration.

  Even in the 10G-EPON system, the maximum number of ONUs that can be connected to one optical transceiver is 32, which is defined by the IEEE standard. The PON control device for 10G-EPON is the PON control device for GE-PON. Higher performance (10 times the data transfer rate) is required, and the cost of the device (such as the purchase price of the device) is also increased. Therefore, in order to employ the 10G-EPON system, it is an issue to reduce the system cost per ONU as much as possible. For example, Patent Document 1 proposes a technique that enables connection of 33 or more ONUs to one optical transceiver by using an optical amplifier.

JP 2012-19353 A

“Technology Basic Course [GE-PON Technology] 1st PON”, NTT Technical Journal, Vol. 17, no. 8, pp. 71-74, 2005.

However, when an optical amplifier is used as in the technique described in Patent Document 1, there is a problem that the cost of the optical amplifier is higher than that of an electrical circuit component (LSI or the like).
Therefore, prior to the present application, the inventors of the present application studied a method for reducing the system cost per ONU without using an optical amplifier. Specifically, in the OLT, an upstream frame of one optical transceiver is selected from an upstream frame of N optical transceivers between N (N is an integer of 2 or more) optical transceivers and a PON control circuit. It has been considered to provide a selection / distribution circuit that outputs to the PON control circuit and outputs the downstream frame of the PON control circuit to N optical transceivers.

According to this prior study example, it becomes possible to accommodate “N × 32” ONUs in the OLT, and the system cost per ONU can be made smaller than that of the conventional PON system.
However, in the OLT according to the above-described prior examination example, the selection / distribution circuit outputs a signal indicating whether an optical signal is input to the optical transceiver (hereinafter referred to as “LOS (Loss Of Signal) ”), the upstream frame of one optical transceiver to be output to the PON control circuit is selected. Therefore, when the LOS signal fluctuates due to, for example, EMI noise, the selection / distribution circuit May malfunction. For example, when the LOS signal fluctuates due to noise, there is a possibility that a frame of an optical transceiver different from the optical transceiver to be originally selected may be selected, or an upstream frame of a plurality of optical transceivers may be selected simultaneously.

  The present invention has been made in view of the above problems, and an object of the present invention is to prevent malfunction caused by fluctuation of the LOS signal in an OLT that selects an upstream frame from an optical transceiver based on the LOS signal. is there.

  The station side device (1, 4, 5) according to the present invention includes a plurality of subscriber side devices (3) connected via first to nth (n ≧ 2) optical splitters (2_1 to 2_n). A station-side device that transfers a frame to and from a host device, connected to the first to n-th optical splitters on a one-to-one basis, and an optical signal light related to a downstream frame to the subscriber-side device A binary LOS indicating whether or not an optical signal related to the upstream frame is inputted, and conversion into an optical signal related to the upstream frame from the subscriber side device and conversion to an electrical signal The upstream frame and the downstream frame are exchanged between the first to Nth optical transceivers (11_1 to 11_n, 41_1 to 41_n) that output signals (14_1 to 14_n) and the higher-level device, and each of the subscriptions From the user side device A PON control circuit (12, 42, 52) for allocating a communication band for uplink frame transmission to each of the subscriber side devices in a time division manner so that the uplink frame is transmitted at The upstream frame of one optical transceiver is selected from the upstream frames of the N optical transceivers and is output to the PON control circuit, and the downstream frame from the PON control circuit is transmitted to the first to nth optical transceivers. And a selection / distribution circuit (13, 23, 43, 53) that outputs the data, and the selection / distribution circuit is provided corresponding to each optical transceiver, and the logical value of the corresponding LOS signal is constant. It is determined whether or not a certain state has continued for a predetermined period. When the logical value of the LOS signal continues for a predetermined period, a determination signal corresponding to the continued logical value is output. Based on the determination unit (15_1 to 15_n) and the determination signal output from the determination unit, a selection is made to select and output the upstream frame of one optical transceiver from the upstream frames of the first to n-th optical transceivers. Circuit (17, 27, 47, 530, 531).

  In the above-mentioned station side device, when the period during which the LOS signal is the first logical value (low level: 0) exceeds the first threshold value (Vdf), the determination unit outputs the determination signal to the second logical value ( When the period when the LOS signal is the second logic value exceeds a second threshold value (Vdr), the determination signal is changed from the first logic value to the first logic value. You may make it switch to a 2nd logic value.

  In the station side device, the determination unit (15B), when all the determination signals other than the determination unit are logical values (high level: 1) indicating that the optical signal is not input, The determination signal corresponding to the determination result of the corresponding logical value of the LOS signal is output, and at least one of the determination signals other than the determination unit is a logical value (low level) indicating that the optical signal is input. : 0), the determination signal having a logical value (high level: 1) indicating that the optical signal is not input may be output.

  In the above station apparatus, the optical transceiver outputs the LOS signal of the first logical value when the optical signal is input, and the second logical value of the optical transceiver when the optical signal is not input. The LOS signal may be output, and the second threshold value (Vdr) may be larger than the first threshold value (Vdf).

  An optical transmission system (100) according to the present invention includes the station side devices (1, 4, 5), the first to nth optical splitters (2_1 to 2_n), and the first to nth optical splitters. And a plurality of subscriber-side devices (3) connected to each other.

  In the above description, as an example, constituent elements on the drawing corresponding to the constituent elements of the invention are represented by reference numerals with parentheses.

  According to the present invention, in the OLT that selects an upstream frame from the optical transceiver based on the LOS signal, it is possible to prevent malfunction due to fluctuation of the LOS signal.

FIG. 1 is a diagram illustrating a configuration of a PON system including a station side device (OLT) according to the first embodiment. FIG. 2 is a diagram illustrating an internal configuration of the selection / distribution circuit in the OLT according to the first embodiment. FIG. 3 is a diagram illustrating a relationship between a determination signal by the determination unit and the LOS signal in the OLT according to the first embodiment. FIG. 4 is a diagram illustrating an example of an internal configuration of a determination unit in the OLT according to the first embodiment. FIG. 5 is a diagram illustrating another example of the internal configuration of the determination unit in the OLT according to the first embodiment. FIG. 6 is a diagram illustrating an internal configuration of a selection / distribution circuit in the OLT according to the second embodiment. FIG. 7 is a diagram illustrating an internal configuration of a selection / distribution circuit in the OLT according to the third embodiment. FIG. 8 is a diagram illustrating an internal configuration of a selection / distribution circuit in the OLT according to the fourth embodiment. FIG. 9 is a diagram illustrating a configuration example of a conventional GE-PON system. FIG. 10 is a diagram illustrating another configuration example of the conventional GE-PON system.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<< Embodiment 1 >>
FIG. 1 is a diagram illustrating a configuration of an optical transmission system including a station side apparatus (OLT) according to the first embodiment.

An optical transmission system 100 shown in FIG. 1 is an optical communication system used in, for example, FTTH, and includes a plurality of optical line terminals (OLTs) 1 connected to an OLT 1 via an optical communication network (PON) 20. The ONU (subscriber side device: Optical Network Unit) 3 is connected to a higher level device (not shown) via the OLT 1 to have a function of transferring frames between each ONU 3 and the higher level device. Yes.
In the optical transmission system 100, frame communication is performed between the OLT 1 and the ONU 3 by transmitting and receiving optical signals via n (n ≧ 2: n is an integer of 2 or more) optical splitters 2_1 to 2_n and optical fibers. The OLT 1 and the host device perform frame communication via a host network (not shown) such as the Internet.

  Specific examples of the optical communication network 20 include PON systems such as GE-PON standardized by IEEE 802.3ah and 10G-EPON standardized by IEEE 802.3av.

  The ONU 3 is an optical line terminating device installed in the user's home. Specifically, the ONU 3 converts an electrical signal output from a terminal device such as a user's PC into an optical signal, transfers the signal to the OLT 1 via the optical splitters 2_1 to 2_n, and receives the signals via the optical splitters 2_1 to 2_n. The optical signal from the OLT 1 is converted into an electrical signal.

  The optical splitters 2_1 to 2_n (hereinafter collectively referred to as “optical splitter 2”) form an optical transmission path between the ONU 3 and the OLT 1. The optical splitter 2 is an optical device that combines and outputs a plurality of input optical signals, and branches and outputs the combined optical signals.

  The OLT 1 is an optical line termination device installed on a station side that provides an optical connection service, and includes a plurality of ONUs 3 connected via an optical splitter 2 that forms an optical transmission path and a host device (not shown). Frame transfer processing between them. For example, the OLT 1 transfers an optical signal transmitted from the ONU 3 via the optical splitter 2 to a host device (for example, a network such as the Internet), while converting the electrical signal transmitted from the host device into an optical signal, Transfer to the ONU 3 via the optical splitter 2. The OLT 1 also performs optical communication in the section PON between the OLT 1 and the ONU 3 and monitors and controls the ONU 3 and the like.

  As shown in FIG. 1, the OLT 1 includes optical transceivers 11_1 to 11_n, a PON control circuit 12, and a selection / distribution circuit 13.

  Optical transceivers 11_1 to 11_n (hereinafter collectively referred to as “optical transceivers 11”) are provided corresponding to each of the optical splitters 2_1 to 2_n, and a plurality (maximum of 32) are provided via the corresponding optical splitter 2. Connected to the ONU 3. Specifically, as shown in FIG. 1, one optical transceiver 11 in the OLT 1 is connected to one side of one optical splitter 2 via an optical transmission line, and the other side of the optical splitter 2 is connected to the other side. A plurality of (up to 32) ONUs 3 are connected in common through the optical transmission line PON. As a result, the OLT 1 is connected to the maximum (N × 32) ONUs 3 in total via the n optical transceivers 11_1 to 11_n and the n optical splitters 2_1 to 2_n.

  The optical transceiver 11 performs electrical-optical conversion for converting an electrical signal related to a downstream frame to be transmitted from the host device to the ONU 3 into an optical signal, and also electrically transmits an optical signal related to the upstream frame to be transmitted from the ONU 3 to the device or the like. Opto-electric conversion is performed to convert the signal. Also, each of the optical transceivers 11_1 to 11_n determines whether or not an optical signal is input from the ONU 3, and outputs LOS signals 14_1 to 14_n corresponding to the determination result.

  Here, the LOS signals 14_1 to 14_n (collectively referred to as “LOS signal 14”) are binary signals indicating whether or not an optical signal is input to the optical transceiver 11. In this specification, the LOS signal 14 is “1 (high level)” when no optical signal is input to the optical transceiver 11, and “0 (low level)” when an optical signal is input. However, depending on the subsequent circuit (logic), it may be a positive logic signal.

  The PON control circuit 12 transmits / receives an electrical signal to / from an upper network, so that an upstream frame and a downstream frame are exchanged with an upper apparatus, and an upstream frame is transmitted from each ONU 3 at different times. , And a function of allocating a communication band for uplink frame transmission to each of these ONUs 3 in a time division manner.

The selection / distribution circuit 13 selects one upstream frame from the upstream frames of the optical transceivers 11_1 to 11_n and outputs the selected upstream frame to the PON control circuit 12, and the downstream frame output from the PON control circuit 12 to the optical transceivers 11_1 to 11_n. Output.
FIG. 2 is a diagram illustrating an internal configuration of the selection / distribution circuit 13 in the OLT according to the first embodiment. As shown in the figure, the selection / distribution circuit 13 includes determination units 15_1 to 15_n, a selection circuit 17, and a distribution circuit 18.

  Determination units 15_1 to 15_n (hereinafter collectively referred to as “determination unit 15”) are provided corresponding to each of the optical transceivers 11_1 to 11_n, and the logic of the LOS signal output from the corresponding optical transceiver. It is a functional unit that determines a value. Specifically, the determination units 15_1 to 15_n determine whether the state in which the logical value of the corresponding LOS signal 14 is constant continues for a predetermined period, and when the logical value of the LOS signal continues for a predetermined period, This is a circuit that outputs binary determination signals 16_1 to 16_n (collectively referred to as “determination signal 16”) corresponding to the continued logical values. For example, the determination unit 15 outputs a determination signal 16 having a logical value “1” when the LOS signal 14 outputs “1” for a predetermined period, and outputs a logical value when the LOS signal 14 outputs “0” for a predetermined period. A judgment signal of “0” is output. Details of the determination unit 15 will be described later.

  The distribution circuit 18 is a circuit for supplying the downstream frame output from the PON control circuit 12 to each optical transceiver 11. As shown in FIG. 2, the distribution circuit 18 is composed of, for example, a buffer circuit BF. The buffer circuit BF receives the downlink frame TX output from the PON control circuit 12, and outputs (distributes) the input downlink frame TX to the optical transceivers 11_1 to 11_n in common.

  The selection circuit 17 is a circuit for selecting and outputting the uplink frame of one optical transceiver from the uplink frames of the optical transceivers 11_1 to 11_n based on the determination signals 16_1 to 16_n output from the determination units 15_1 to 15_n. . Specifically, the selection circuit 17 includes AND circuits (AND circuits) 170_1 to 170_n and an n-input OR circuit (OR circuit) 171.

Logical product circuits (AND circuits) 170_1 to 170_n are provided for the optical transceivers 11_1 to 11_n, and perform a logical product of the uplink frame output from the corresponding optical transceiver 11 and the inverted value of the corresponding determination signals 16_1 to 16_n. Calculate and output. For example, the AND circuit 170_n calculates and outputs a logical product of the uplink frame RX_n output from the optical transceiver 11_n and the inverted value of the determination signal 16_n of the determination unit 15_n.
Here, as described above, the LOS signal 14 is a signal indicating whether or not the optical signal from the splitter 2 is input to the optical transceiver 11, and becomes “1” when the optical signal is not input. When an optical signal is input, it is “0”. Therefore, the determination signal 16 for the LOS signal 14 is similarly “1” when no optical signal is input, and is “0” when an optical signal is input.
Thus, the AND circuits 170_1 to 170_n output the input uplink frames RX_1 to RX_n when the input determination signal 16 is “0 (with optical signal)”, and the input determination signal 16 is In the case of “1 (no optical signal)”, the output of the input upstream frame is stopped and “0” is output.
Therefore, the uplink frames RX_1 to RX_n output from the corresponding optical transceivers 11_1 to 11_n are masked (gated) by the determination signals 16_1 to 16_n by the logical product circuits 170_1 to 170_n.

The logical sum circuit 171 inputs n logical product values respectively output from the logical product circuits 170_1 to 170_n, and calculates and outputs the logical sum of them.
As a result, among the optical transceivers 11_1 to 11_n, the upstream frame output from the optical transceiver 11 to which the optical signal is input is input to the logical sum circuit 171 via the logical product circuits 170_1 to 170_n, and the logical sum thereof is obtained. Is input to the PON control circuit 12 as the upstream frame RX.

Therefore, in order to correctly receive each uplink frame output RX, each of the AND circuits 170_1 to 170_n is configured so that the uplink frames RX_1 to RX_n from the plurality of optical transceivers 11_1 to 11_n are not simultaneously input to the OR circuit 171. Therefore, it is necessary to mask these upstream frames RX_1 to RX_n by time division.
For this, the PON control circuit 12 performs time-sharing control so that all the ONUs 3 that have established a connection with the OLT 1 through each optical splitter 2 do not emit light (upstream frame transmission) at the same time. realizable.

  In the conventional PON system, each OLT is changed by an algorithm such as Dynamic Bandwidth Allocation (DBA) so that a plurality of ONUs connected to one optical splitter do not emit light (uplink frame transmission) at the same time. Uplink bandwidth allocation (grant allocation) is performed for the ONU.

In the OLT 1 of the present embodiment, by applying such an algorithm, the PON control circuit 12 performs a session with the OLT 1 among the maximum n × 32 ONUs 3 connected to the n optical splitters 2_1 to 2_n. Uplink allocation (grant allocation) for allocating a communication band for uplink frame transmission in a time-sharing manner is performed on all ONUs 3 that have established connections so that these ONUs 3 emit light at different times (uplink frame transmission).
As a result, only one ONU 3 among the ONUs 3 emits light (upstream frame transmission), and only the LOS signal 14 from one optical transceiver 11 that accommodates the ONU 3 becomes “0”.

  Note that a registration request (Register Request) frame that is a control frame used for a request for connection of a new ONU or the like is permitted by the IEEE standard to allow a plurality of ONUs to simultaneously emit light (uplink frame transmission). Therefore, during the period (Discovery Window) during which transmission of the registration request frame is permitted, the LOS signals 14 of the plurality of optical transceivers 11 may be simultaneously 0, and when they become 0 simultaneously. In some cases, the PON control circuit 12 may not normally receive a registration request (Register Request) frame.

  However, during the period during which registration request (Register Request) frames are permitted to be transmitted (Discovery Window), even in the conventional PON system, a plurality of ONUs connected to the same optical splitter can simultaneously register (Register Request) frames. In such a case, the OLT has a specification that a registration request (Register Request) frame that cannot be normally received may be ignored (discarded). The OLT 1 of the present embodiment also has a specification that a registration request (Register Request) frame that cannot be normally received by the PON control circuit 12 may be ignored (discarded).

  By configuring the OLT 1 as described above, when an optical transceiver 11 similar to the conventional PON system is used, the OLT 1 according to the present embodiment communicates with a maximum of “n × 32” ONUs 3. Is possible. For example, it is possible to communicate with a maximum of 128 units when n = 4, and with a maximum of 512 units when n = 16. That is, according to the OLT 1, the system cost per ONU can be made smaller than that of the conventional PON system.

Next, the determination unit 15 will be described in detail.
As described above, the determination unit 15 determines whether or not the state in which the logical value of the corresponding LOS signal 14 is constant continues for a predetermined period, and when the logical value of the LOS signal continues for a predetermined period, A binary decision signal 16 corresponding to the continued logical value is output.

FIG. 3 is a diagram illustrating a relationship between the determination signal by the determination unit and the LOS signal.
As illustrated in FIG. 3, when the state in which the LOS signal 14 is “1” continues for a period Tdr or longer, the determination unit 15 determines that the signal level (logical value) of the LOS signal 14 is “1” and determines The signal 16 is set to “1”. Further, the determination unit 15 determines that the signal level (logical value) of the LOS signal 14 is “0” when the state in which the LOS signal 14 is “0” continues for the period Tdf or longer, and sets the determination signal 16 to “0”. ".

  On the other hand, as illustrated in FIG. 3, when the LOS signal 14 is “1” only in the period t 1 shorter than the period Tdr in the state where the LOS signal is “0”, the determination unit 15 determines that the LOS signal 14 It is determined that the state in which the signal level (logical value) of “0” is “0” is maintained, and the determination signal 16 whose logical value is “0” is continuously output. As shown in FIG. 3, in the state where the LOS signal is “1”, when the LOS signal 14 becomes “0” only for the period t 2 shorter than the period Tdf, the determination unit 15 determines that the LOS signal 14 It is determined that the signal level (logical value) of “1” is maintained, and the determination signal 16 having the logical value “1” is continuously output.

  According to this, since a short-time fluctuation (Tdr, time less than Tdf) of the LOS signal 14 is not transmitted to the subsequent AND circuit 170, a malfunction during upstream frame transfer caused by fluctuation of the LOS signal 14 due to noise or the like. Can be prevented.

Next, a specific circuit configuration for realizing the determination unit 15 will be described.
FIG. 4 is a diagram illustrating an example of an internal configuration of the determination unit 15 in the OLT according to the first embodiment.
In the drawing, the case where the determination unit 15A is the determination circuit 15_1 that determines the LOS signal 14_1 is shown as an example. However, the determination unit 15A determines the other LOS signals 14_2 to 14_n that are determination circuits 15_2 to 15_n. It can be similarly applied to.

  The determination unit 15A illustrated in FIG. 4 includes, for example, an inverting circuit (inverter) 150, D flip-flop circuits (DFF) 151 to 153, counters (CNTR) 154 and 155, threshold determination units 156 and 157, and an RS flip-flop circuit. (RSFF) 158.

  The counter 154 counts a period during which the LOS signal 14_1 is “0”. On the other hand, the counter 155 counts a period during which the LOS 14_1 is “1”. For example, when the LOS signal 14_1 is “0”, the counter 155 is in a reset state (count value “0” is output), while the counter 154 performs a count-up operation by the clock signal CLK. When the LOS signal 14_1 is "1", the counter 154 is in a reset state (count value "0" is output), while the counter 155 performs a count-up operation with the clock signal CLK.

  The threshold value determination unit 156 outputs “0” when the count value of the counter 154 is smaller than the threshold value corresponding to the above-described period Tdf, and when the count value of the counter 154 is larger than the threshold value corresponding to the period Tdf. Outputs “1”. Further, the threshold value determination unit 157 outputs “0” when the count value of the counter 155 is smaller than the threshold value corresponding to the above-described period Tdr, and the count value of the counter 155 is larger than the threshold value corresponding to the period Tdr. In this case, “1” is output.

  The RSFF 158 inputs the output signal of the threshold determination unit 156 to the R (reset) terminal and inputs the output signal of the threshold determination unit 157 to the S (set) terminal. According to this, when the output signal (S terminal) of the threshold determination unit 157 becomes “1” in the state where the output signal (R terminal) of the threshold determination unit 156 is “0”, the RSFF 158 reads “ When “1” is output and the output signal (R terminal) of the threshold determination unit 156 becomes “1”, “0” is output from the RSFF 158, and in other cases, the previous output value is maintained. Is done. As a result, when the logical value of the LOS signal 14 is stable for a period longer than Tdr and Tdf, the determination signal 16 corresponding to the logical value is generated.

The determination unit 15 can also be realized by the circuit shown in FIG.
FIG. 5 is a diagram illustrating another example of the internal configuration of the determination unit 15 in the OLT according to the first embodiment.
The determination unit 15B shown in the figure outputs a determination signal of “1 (no optical signal)” when at least one of determination signals other than the determination unit is “0 (with optical signal)”. When all determination signals other than the determination unit are “1 (no optical signal)”, a determination signal having a logical value corresponding to the determination result of the LOS signal is output.

Specifically, the determination unit 15B further includes AND circuits 159 and 160 in addition to the functional unit of the determination unit 15A.
The logical product circuit 160 receives the determination signal 16 output from the determination unit 15B other than the determination unit 15B, calculates the logical product of the input determination signals 16, and outputs the result. For example, the AND circuit 160 in the determination unit 15B_1 corresponding to the optical transceiver 11_1 receives the determination signals 16_2 to 16_n output from the determination units 15B_2 to 15B_n corresponding to the other optical transceivers 11_2 to 11_n, and determines all of them. The logical product of the signals 16_2 to 16_n is calculated and output. The AND circuit 159 calculates the logical product of the output signal of the threshold value determination unit 156 and the output signal of the AND circuit 160 and outputs the calculation result to the R terminal of the RSFF 158.

According to the determination unit 15B, only when all the determination signals 16 output from the other determination units 15B other than the determination unit 15B are “1”, the determination signals 16 of the determination unit 15B are changed from “1” to “1”. Switching to 0 "is allowed. Accordingly, it is possible to prevent a plurality of determination signals 16_1 to 16_n corresponding to the LOS signals 14_1 to 14_n from simultaneously becoming “0”.
For example, when at least one of the determination signals 16_2 to 16_n corresponding to the optical transceivers 11_2 to 11_n outputs “0 (with optical signal)”, the LOS signal 14_1 corresponding to the optical transceiver 11_1 is longer than the period Tdf. Even if the period becomes “0 (with optical signal)”, the determination signal 16_1 corresponding to the optical transceiver 11_1 does not become “0”. Thereafter, when all the determination signals 16_2 to 16_n corresponding to the other optical transceivers 11_2 to 11_n are “1 (no optical signal)”, the determination signal 16_1 corresponding to the optical transceiver 11_1 is “0 (there is an optical signal)”. "

  Note that the period Tdr and the period Tdf as threshold values do not have to be the same value, and may be different values. For example, by setting the threshold values of the threshold value determination units 156 and 157 so that Tdr> Tdf, the determination signal 16 outputting “0 (with optical signal)” becomes “1 (without optical signal)”. Since it becomes difficult, the stability of communication when the optical transceiver 11 outputs an optical signal can be further enhanced. On the contrary, Tdr <Tdf may be set so that the determination signal 16 does not easily become “0 (with optical signal)”.

  As described above, according to the OLT according to the first embodiment, the logical value is determined based on the period during which the logical value of the LOS signal continues, and the uplink frame from the optical transceiver is selected based on the determination result (determination signal). Therefore, it is possible to prevent malfunction during uplink frame transfer caused by fluctuations in the LOS signal due to noise or the like as compared with the case where the uplink frame from the optical transceiver is selected based on the LOS signal itself.

  In addition, the determination unit for determining the logical value of the LOS signal 14 is realized by the circuit (determination unit 15A) shown in FIG. No determination signal 16 can be easily generated.

  In addition, by realizing the determination unit for determining the logical value of the LOS signal 14 by the circuit (determination unit 15B) shown in FIG. 5, as in the determination unit 15A shown in FIG. 4, than the periods Tdr and Tdf. It is possible to generate a determination signal 16 that is not affected by fluctuations in the LOS signal 14 in a short time, and to prevent a plurality of determination signals 16 from simultaneously becoming “0 (with optical signal)”.

<< Embodiment 2 >>
FIG. 6 is a diagram illustrating an internal configuration of the OLT according to the second embodiment.
The selection / distribution circuit 23 shown in the figure is different from the selection / distribution circuit 13 in the OLT according to the first embodiment in the internal configuration of the selection circuit, and the other configurations are the same as those of the selection / distribution circuit 13.

  In FIG. 6, the same components as those of the selection / distribution circuit 13 in the OLT according to the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. 6 shows only the selection circuit 27 and the peripheral circuits connected thereto in the selection / distribution circuit 23, and the distribution circuit 18 that distributes the downstream frame output from the PON control circuit 12 is not shown. doing. FIG. 6 shows an example where n = 8, but the value of n is not particularly limited.

  Specifically, the selection / distribution circuit 23 includes a selection circuit 27 instead of the selection circuit 17 described above. The selection circuit 27 is configured using selectors (Sel) 270_1 to 270_7 and logical product circuits 271 to 274, and realizes the same logic as that of the selection circuit 17 described above. That is, the selection circuit 27 selects the uplink frame of one optical transceiver 11 from the uplink frames of the optical transceivers 11_1 to 11_8 based on the determination signals 16_1 to 16_n from the determination units 15_1 to 15_n, and sets the uplink frame RX as the uplink frame RX. This is given to the PON control circuit 12.

  As the determination unit 15 in the selection / distribution circuit 23, the circuit (determination unit 15A) shown in FIG. 4 or the circuit (determination unit 15B) shown in FIG. Can do.

  In the selection circuit 27, for example, when only the LOS signal of the optical transceiver 11_5 is “0”, that is, the determination signals 16_1 to 16_4 and 16_6 to 16_8 of the optical transceivers 11_1 to 11_4 and 11_6 to 11_8 other than the optical transceiver 11_5 are “1”. In this case, the upstream frame output from the optical transceiver 11_5 is input to the PON control circuit 12 via the selectors 270_3, 270_6, and 270_7. For example, when only the LOS output of the optical transceiver 11_4 is “0”, the selectors 270_2, 270_5, and 270_7 select and output the signal input to the input terminal on the “0” side. As a result, the upstream frame output from the optical transceiver 11_4 passes through the selectors 270_2, 270_5, and 270_7 and is input to the PON control circuit 12.

  In addition, when only the determination signal (LOS signal) of one optical transceiver among the other optical transceivers 11_1 to 11_3 and 11_6 to 11_8 is “0”, some sectors are input on the “0” side. By selecting and outputting the signal input to the terminal, the output of the optical transceiver whose determination signal is “0” is input to the PON control circuit 12.

  As described above, according to the OLT selection / distribution circuit 23 according to the second embodiment, the logical value of the LOS signal continues, not the LOS signal itself, as in the OLT selection / distribution circuit 13 according to the first embodiment. Since the uplink frame from the optical transceiver 11 is selected based on the determination signal determined based on the period, it is possible to prevent malfunction during uplink frame transfer caused by fluctuation of the LOS signal due to noise or the like.

<< Embodiment 3 >>
FIG. 7 is a diagram illustrating an internal configuration of a selection / distribution circuit in the OLT according to the third embodiment. The OLT 4 shown in the figure is an OLT corresponding to the 10G-EPON system, and has a configuration considering the following (1) and (2).
(1) An optical transceiver for 10G-EPON may have two upstream frame outputs, an upstream frame of 10 Gbit / s and an upstream frame of 1 Gbit / s.
(2) When both the ONU for 10G-EPON and the ONU for GE-PON are connected to the same OLT, the PON control circuit outputs 10 Gbit / s downstream frames and 1 Gbit / s downstream frames as downstream frame outputs. Having two, both downstream frames need to be output (distributed) to all optical transceivers.

  That is, the optical transceivers 41_1 to 41_n, the PON control circuit 42, and the selection / distribution circuit 43 constituting the OLT 4 according to the third embodiment are configured as follows in consideration of the above (1) and (2). Yes.

  The optical transceivers 41_1 to 41_n (generally referred to as “optical transceiver 41”) include an output port for 10 Gbit / s and an output port for 1 Gbit / s as output ports of the upstream frame. As a downstream frame input port, an input port for 10 Gbit / s and an input port for 1 Gbit / s are provided.

  The PON control circuit 42 has a configuration corresponding to both 10 Gbit / s and 1 Gbit / s upstream frame inputs, and as a downstream frame output port, an output port for 10 Gbit / s and an output port for 1 Gbit / s And. In addition, the PON control circuit 42 determines whether to permit frame transmission at 10 Gbit / s or to permit frame transmission at 1 Gbit / s at the time of uplink band allocation, and selects and distributes the result as a selection signal S10G_1G. Output to the circuit 43.

  The selection / distribution circuit 43 includes determination units 15_1 to 15_n, selectors SL_1 to SL_n, a selection circuit 47, and a distribution circuit 48.

  In the selection / distribution circuit 43, the selectors SL_1 to SL_n receive the selection signal S10G_1G from the PON control circuit 42, and as the uplink frame outputs of the optical transceivers 41_1 to 41_n, the selectors SL_1 to SL_n are for 10 Gbit / s of the optical transceivers 41_1 to 41_n The upstream frame from any one of the output port and the output port for 1 Gbit / s is selected and supplied to the selection circuit 47.

  The selection circuit 47 includes AND circuits 470_1 to 470_n and an OR circuit 471. The AND circuit 470_1 is provided for each of the optical transceivers 41_1 to 41_n, and performs an AND operation between the uplink frame output from the corresponding selector SL (optical transceiver 41) and the inverted value of the determination signal 16 of the corresponding determination unit 15. Calculate and output.

  The logical sum circuit 471 receives n logical product values output from the logical product circuits 470_1 to 470_n, calculates the logical sum of the logical product values, and provides the result to the PON control circuit 42 as upstream frame data RX.

  The distribution circuit 48 includes a buffer circuit BF_1 and a buffer circuit BF_2. The buffer circuit BF_1 inputs the downstream frame (downstream frame of 10 Gbit / s) TX_1G from the 1 Gbit / s output port of the PON control circuit 42, and the 1 Gbit / s input port of the optical transceivers 41_1 to 41_n. Distribute. Further, the buffer circuit BF_2 inputs the downstream frame (downstream frame of 10 Gbit / s) TX_10G from the 10 Gbit / s output port of the PON control circuit 42, and inputs to the 10 Gbit / s input port of the optical transceivers 41_1 to 41_n. Distribute to them.

  As described above, according to the OLT according to the third embodiment, similar to the OLT according to the first embodiment, not based on the LOS signal itself but based on the determination signal determined based on the period during which the logical value of the LOS signal continues. Since the upstream frame from the optical transceiver is selected, even in the 10G-EPON system, it is possible to prevent malfunction during upstream frame transfer caused by fluctuations in the LOS signal due to noise or the like.

<< Embodiment 4 >>
FIG. 8 is a diagram illustrating an internal configuration of a selection / distribution circuit in the OLT according to the fourth embodiment.
The OLT 5 shown in the figure is another example of the OLT corresponding to the 10G-EPON system. Note that in the OLT 5 according to the fourth embodiment, the same components as those of the OLT 4 according to the third embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  The OLT 5 includes optical transceivers 41_1 to 41_n, a PON control circuit 52, and a selection / distribution circuit 53.

  The PON control circuit 52 has a configuration corresponding to both 10 Gbit / s and 1 Gbit / s upstream frame inputs, and as a downstream frame output port, an output port for 10 Gbit / s and an output port for 1 Gbit / s And.

  The selection / distribution circuit 53 includes determination units 15_1 to 15_n, an RX_10G selection circuit 530, an RX_1G selection circuit 531 and a distribution circuit 48.

  In the selection / distribution circuit 53, the RX_10G selection circuit 530 has the same circuit configuration as the selection circuit 17 (see FIG. 2) and the selection circuit 27 (see FIG. 6). Specifically, the RX_10G selection circuit 530 outputs the 10 Gbit / s uplink frames RX_10G_1 to RX_10G_n output from the 10 Gbit / s output ports of the optical transceivers 41_1 to 41_n based on the determination signals 16_1 to 16_n. The upstream frame of one optical transceiver 41 is selected from among them, and is sent to the input port for 10 Gbit / s of the PON control circuit 52.

  The RX_1G selection circuit 531 has the same configuration as the RX_10G selection circuit 530. Specifically, the RX_1G selection circuit 531 selects the 1 Gbit / s uplink frames RX_1G_1 to RX_1G_n output from the 1 Gbit / s output ports of the optical transceivers 41_1 to 41_n based on the determination signals 16_1 to 16_n. The upstream frame of one optical transceiver 41 is selected from among them, and is sent to the input port for 1 Gbit / s of the PON control circuit 52.

  The distribution circuit 48 including the buffer circuit BF_1 and the buffer circuit BF_2 is the same as the OLT 4 according to the third embodiment. That is, the buffer circuit BF_1 inputs a downstream frame (downstream frame of 10 Gbit / s) TX_1G from the 1 Gbit / s output port of the PON control circuit 52, and inputs to the 1 Gbit / s input port of the optical transceivers 41_1 to 41_n. Distribute to them. Further, the buffer circuit BF_2 inputs the downstream frame (downstream frame of 10 Gbit / s) TX_10G from the 10 Gbit / s output port of the PON control circuit 52, and inputs it to the 10 Gbit / s input port of the optical transceivers 41_1 to 41_n. Distribute to them.

  As described above, according to the OLT according to the fourth embodiment, similar to the OLT according to the third embodiment, not based on the LOS signal itself but based on the determination signal determined based on the period during which the logical value of the LOS signal continues. Since the upstream frame from the optical transceiver is selected, even in the 10G-EPON system, it is possible to prevent malfunction during upstream frame transfer caused by fluctuations in the LOS signal due to noise or the like.

  Although the invention made by the present inventors has been specifically described based on the embodiments, it is needless to say that the present invention is not limited thereto and can be variously modified without departing from the gist thereof. Yes.

  For example, in the above-described embodiment, the optical transmission system 100 is described as an example in which the optical communication network 20 includes a GE-PON system or a 10G-EPON system using GE-PON or 10G-EPON as the optical communication network 20. The present invention is not limited, and can be applied to an optical transmission system using another optical communication network.

  DESCRIPTION OF SYMBOLS 100 ... Optical transmission system, 1, 4, 5 ... OLT, 2_1-2_n ... Optical splitter, 3 ... ONU, 11, 11_1-11_n, 41, 41_1-41_n ... Optical transceiver, 12, 42, 52 ... PON control circuit, 13, 23, 43, 53 ... selection / distribution circuit, 14, 14_1 to 14_n ... LOS signal, 15, 15_1 to 15_n ... determination unit, 16, 16_1 to 16_n ... determination signal, 17, 27, 47, 530, 531 ... Selection circuit 18, 48... Distribution circuit, Tdr... High level determination threshold (period), Tdf. Low level determination threshold (period), 20... Optical communication network (PON).

Claims (7)

A station-side device that transfers frames between a plurality of subscriber-side devices and higher-level devices connected via first to n-th (n ≧ 2) optical splitters,
One-to-one connection to the first to nth optical splitters, conversion of an electrical signal related to a downstream frame to the subscriber side device into an optical signal, and light related to an upstream frame from the subscriber side device First to Nth optical transceivers that perform conversion of signals into electrical signals and output binary LOS signals that indicate whether or not an optical signal related to the upstream frame is input;
The uplink frame and the downlink frame are exchanged with the host device, and the uplink frame is transmitted to each subscriber side device so that the uplink frame is transmitted from each subscriber side device at different times. A PON control circuit that allocates a reliable communication band in a time-sharing manner;
The upstream frame of one optical transceiver is selected from the upstream frames of the first to Nth optical transceivers and is output to the PON control circuit, and the downstream frame from the PON control circuit is selected from the first to nth frames. And a selection / distribution circuit that outputs to the optical transceiver of
The selection / distribution circuit includes:
It is provided for each of the optical transceivers, and it is determined whether or not the state in which the logical value of the corresponding LOS signal is constant continues for a predetermined period.When the logical value of the LOS signal continues for a predetermined period, A determination unit that outputs a determination signal corresponding to the continued logical value;
A selection circuit that selects and outputs an upstream frame of one optical transceiver from upstream frames of the first to n-th optical transceivers based on the determination signal output from the determination unit; Station side device to do. In the station side apparatus described in Claim 1,
The first to Nth optical transceivers are:
As an upstream frame output port, it has an output port for 10 Gbit / s and an output port for 1 Gbit / s,
The selection / distribution circuit includes:
In response to a selection signal from the PON control circuit, either an output port for 10 Gbit / s or an output port for 1 Gbit / s of the optical transceiver is used as an upstream frame of the first to n-th optical transceivers. Comprising first to Nth selectors for selecting an upstream frame from an output port;
The selection circuit selects and outputs one uplink frame from the uplink frames selected by the first to nth selectors based on the determination signal output from the determination unit. Side device. In the station side apparatus in the optical transmission system according to claim 1,
The first to nth optical transceivers are:
As an upstream frame output port, it has an output port for 10 Gbit / s and an output port for 1 Gbit / s,
The selection circuit includes:
Based on the determination signal output from the determination unit, the uplink frame of one optical transceiver is selected from the uplink frames output from the 10 Gbit / s output ports of the first to n-th optical transceivers. A first selection circuit for outputting to the PON control circuit;
Based on the determination signal output from the determination unit, the uplink frame output of one optical transceiver is output from the uplink frame outputs output from the 1 Gbit / s output ports of the first to n-th optical transceivers. And a second selection circuit that selects and outputs the second selection circuit to the PON control circuit. In the station apparatus as described in any one of Claims 1 thru | or 3,
The determination unit
When the period during which the LOS signal is the first logic value exceeds the first threshold, the determination signal is switched from the second logic value to the first logic value, and the period during which the LOS signal is the second logic value When the value exceeds a second threshold, the determination signal is switched from the first logical value to the second logical value. In the station side apparatus as described in any one of Claims 1 thru | or 4,
The determination unit
When all the determination signals other than the determination unit are logical values indicating that the optical signal is not input, the determination signals corresponding to the determination result of the logical value of the corresponding LOS signal are output. When at least one of the determination signals other than the determination unit is a logical value indicating that the optical signal is input, the determination signal having a logical value indicating that the optical signal is not input. A station side device characterized by outputting. In the station side apparatus described in Claim 4,
The optical transceiver outputs the LOS signal having the first logical value when the optical signal is input, and outputs the LOS signal having the second logical value when the optical signal is not input. ,
The station side apparatus, wherein the second threshold is larger than the first threshold. A station-side device according to any one of claims 1 to 6;
The first to nth optical splitters;
A plurality of subscriber-side devices connected via the first to n-th optical splitters;
An optical transmission system comprising:

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